#!/usr/bin/env python
# License: GPL v3 Copyright: 2016, Kovid Goyal <kovid at kovidgoyal.net>

from binascii import hexlify
from functools import partial

from kitty.fast_data_types import (
    CURSOR_BLOCK,
    VT_PARSER_BUFFER_SIZE,
    base64_decode,
    base64_encode,
    has_avx2,
    has_sse4_2,
    test_find_either_of_two_bytes,
    test_utf8_decode_to_sentinel,
)

from . import BaseTest, parse_bytes


def cnv(x):
    if isinstance(x, memoryview):
        x = str(x, 'utf-8')
    return x


class CmdDump(list):

    def __call__(self, window_id, *a):
        if a and a[0] == 'bytes':
            return
        if a and a[0] == 'error':
            a = a[1:]
        self.append(tuple(map(cnv, a)))

    def get_result(self):
        current = ''
        q = []
        for args in self:
            if args[0] == 'draw':
                current += args[1]
            else:
                if current:
                    q.append(('draw', current))
                    current = ''
                q.append(args)
        if current:
            q.append(('draw', current))
        return tuple(q)


class TestParser(BaseTest):

    def create_write_buffer(self, screen):
        return screen.test_create_write_buffer()

    def write_bytes(self, screen, write_buf, data):
        if isinstance(data, str):
            data = data.encode('utf-8')
        s = screen.test_commit_write_buffer(data, write_buf)
        return data[s:]

    def parse_written_data(self, screen, *cmds):
        cd = CmdDump()
        screen.test_parse_written_data(cd)
        cmds = tuple(('draw', x) if isinstance(x, str) else tuple(map(cnv, x)) for x in cmds)
        self.ae(cmds, cd.get_result())

    def parse_bytes_dump(self, s, x, *cmds):
        cd = CmdDump()
        if isinstance(x, str):
            x = x.encode('utf-8')
        cmds = tuple(('draw', x) if isinstance(x, str) else tuple(map(cnv, x)) for x in cmds)
        parse_bytes(s, x, cd)
        self.ae(cmds, cd.get_result())

    def test_charsets(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb(b'\xc3')
        pb(b'\xa1', ('draw', b'\xc3\xa1'.decode('utf-8')))
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb('\033)0\x0e/_', ('screen_designate_charset', 1, ord('0')), ('screen_change_charset', 1), '/_')
        self.ae(str(s.line(0)), '/\xa0')
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb('\033(0/_', ('screen_designate_charset', 0, ord('0')), '/_')
        self.ae(str(s.line(0)), '/\xa0')

    def test_parser_threading(self):
        s = self.create_screen()

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), 'a\x1b]2;some title'))
        b = self.create_write_buffer(s)
        self.parse_written_data(s, 'a')
        self.assertFalse(self.write_bytes(s, b, ' full\x1b\\'))
        self.parse_written_data(s, ('set_title', 'some title full'))

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), 'a\x1b]'))
        b = self.create_write_buffer(s)
        self.parse_written_data(s, 'a')
        self.assertFalse(self.write_bytes(s, b, '2;title\x1b\\'))
        self.parse_written_data(s, ('set_title', 'title'))

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), 'a\x1b'))
        b = self.create_write_buffer(s)
        self.parse_written_data(s, 'a')
        self.assertFalse(self.write_bytes(s, b, ']2;title\x1b\\'))
        self.parse_written_data(s, ('set_title', 'title'))

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), 'a\x1b]2;some title\x1b'))
        b = self.create_write_buffer(s)
        self.parse_written_data(s, 'a')
        self.assertFalse(self.write_bytes(s, b, '\\b'))
        self.parse_written_data(s, ('set_title', 'some title'), 'b')

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '1\x1b'))
        self.parse_written_data(s, '1')
        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), 'E2'))
        self.parse_written_data(s, ('screen_nel',), ('draw', '2'))

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '1\x1b[2'))
        self.parse_written_data(s, '1')
        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '3mx'))
        self.parse_written_data(s, ('select_graphic_rendition', '23'), 'x')

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '1\x1b'))
        self.parse_written_data(s, '1')
        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '[23mx'))
        self.parse_written_data(s, ('select_graphic_rendition', '23'), 'x')

        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '1\x1b['))
        self.parse_written_data(s, '1')
        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), '23mx'))
        self.parse_written_data(s, ('select_graphic_rendition', '23'), 'x')

        # test full write
        sz = VT_PARSER_BUFFER_SIZE // 3 + 7
        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), b'a' * sz))
        self.assertFalse(self.write_bytes(s, self.create_write_buffer(s), b'b' * sz))
        left = self.write_bytes(s, self.create_write_buffer(s), b'c' * sz)
        self.assertTrue(len(left), 3 * sz - VT_PARSER_BUFFER_SIZE)
        self.assertFalse(self.create_write_buffer(s))
        s.test_parse_written_data()
        b = self.create_write_buffer(s)
        self.assertTrue(b)
        self.write_bytes(s, b, b'')

    def test_base64(self):
        for src, expected in {
            'bGlnaHQgdw==': 'light w',
            'bGlnaHQgd28=': 'light wo',
            'bGlnaHQgd29y': 'light wor',
        }.items():
            self.ae(base64_decode(src.encode()), expected.encode(), f'Decoding of {src} failed')
            self.ae(base64_decode(src.replace('=', '').encode()), expected.encode(), f'Decoding of {src} failed')
            self.ae(base64_encode(expected.encode()), src.replace('=', '').encode(), f'Encoding of {expected} failed')

    def test_simple_parsing(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)

        pb('12', '12')
        self.ae(str(s.line(0)), '12')
        self.ae(s.cursor.x, 2)
        pb('3456', '3456')
        self.ae(str(s.line(0)), '12345')
        self.ae(str(s.line(1)), '6')
        pb(b'\n123\n\r45', ('screen_linefeed',), '123', ('screen_linefeed',), ('screen_carriage_return',), '45')
        self.ae(str(s.line(1)), '6')
        self.ae(str(s.line(2)), ' 123')
        self.ae(str(s.line(3)), '45')
        pb(b'\rabcde', ('screen_carriage_return',), 'abcde')
        self.ae(str(s.line(3)), 'abcde')
        pb('\rßxyz1', ('screen_carriage_return',), 'ßxyz1')
        self.ae(str(s.line(3)), 'ßxyz1')
        pb('ニチ ', 'ニチ ')
        self.ae(str(s.line(4)), 'ニチ ')
        s.reset()
        self.assertFalse(str(s.line(1)) + str(s.line(2)) + str(s.line(3)))
        c1_controls = '\x84\x85\x88\x8d\x8e\x8f\x90\x96\x97\x98\x9a\x9b\x9c\x9d\x9e\x9f'
        pb(c1_controls, c1_controls)
        self.assertFalse(str(s.line(1)) + str(s.line(2)) + str(s.line(3)))
        pb('😀'.encode()[:-1])
        pb('\x1b\x1b%a', '\ufffd', ('Unknown char after ESC: 0x1b',), ('draw', '%a'))

    def test_utf8_simd_decode(self):
        def unsupported(which):
            return (which == 2 and not has_sse4_2) or (which == 3 and not has_avx2)

        def reset_state():
            test_utf8_decode_to_sentinel(b'', -1)

        def asbytes(x):
            if isinstance(x, str):
                x = x.encode()
            return x

        def t(*a, which=2):
            if unsupported(which):
                return

            def parse_parts(which):
                total_consumed = 0
                esc_found = False
                parts = []
                for x in a:
                    found_sentinel, x, num_consumed = test_utf8_decode_to_sentinel(asbytes(x), which)
                    total_consumed += num_consumed
                    if found_sentinel:
                        esc_found = found_sentinel
                    parts.append(x)
                return esc_found, ''.join(parts), total_consumed

            reset_state()
            actual = parse_parts(1)
            reset_state()
            expected = parse_parts(which)
            self.ae(expected, actual, msg=f'Failed for {a} with {which=}\n{expected!r} !=\n{actual!r}')
            return actual

        def double_test(x):
            for which in (2, 3):
                t(x, which=which)
            t(x*2, which=3)
            reset_state()

        # incomplete trailer at end of vector
        t("a"*10 + "😸😸" + "b"*15)

        x = double_test
        x('2:α3')
        x('2:α\x1b3')
        x('2:α3:≤4:😸|')
        x('abcd1234efgh5678')
        x('abc\x1bd1234efgh5678')
        x('abcd1234efgh5678ijklABCDmnopEFGH')

        for which in (2, 3):
            x = partial(t, which=which)
            x('abcdef', 'ghijk')
            x('2:α3', ':≤4:😸|')
            # trailing incomplete sequence
            for prefix in (b'abcd', '😸'.encode()):
                for suffix in (b'1234', '😸'.encode()):
                    x(prefix + b'\xf0\x9f', b'\x98\xb8' + suffix)
                    x(prefix + b'\xf0\x9f\x9b', b'\xb8' + suffix)
                    x(prefix + b'\xf0', b'\x9f\x98\xb8' + suffix)
                    x(prefix + b'\xc3', b'\xa4' + suffix)
                    x(prefix + b'\xe2', b'\x89\xa4' + suffix)
                    x(prefix + b'\xe2\x89', b'\xa4' + suffix)

        def test_expected(src, expected, which=2):
            if unsupported(which):
                return
            reset_state()
            _, actual, _ = t(b'filler' + asbytes(src), which=which)
            expected = 'filler' + expected
            self.ae(expected, actual, f'Failed for: {src!r} with {which=}')

        for which in (1, 2, 3):
            pb = partial(test_expected, which=which)
            pb('ニチ', 'ニチ')
            pb('\x84\x85', '\x84\x85')
            pb('\x84\x85', '\x84\x85')
            pb('\uf4df', '\uf4df')
            pb('\uffff', '\uffff')
            pb('\0', '\0')
            pb(chr(0x10ffff), chr(0x10ffff))
            # Kitty's UTF-8 decoding uses `U+FFFD substitution of maximal subparts
            # <https://www.unicode.org/versions/Unicode16.0.0/core-spec/chapter-3/#G66453>`_,
            # same as in the WHATWG Encoding Standard.
            # This means that ill-formed sequences may be replaced by multiple
            # U+FFFD REPLACEMENT CHARACTERs.
            pb(b'abcd\xf51234', 'abcd\ufffd1234')  # bytes > 0xf4
            pb(b'abcd\xff1234', 'abcd\ufffd1234')  # bytes > 0xf4
            pb(b'"\xbf"', '"\ufffd"')
            pb(b'"\x80"', '"\ufffd"')
            pb(b'"\x80\xbf"', '"\ufffd\ufffd"')
            pb(b'"\x80\xbf\x80"', '"\ufffd\ufffd\ufffd"')
            pb(b'"\xc0 "', '"\ufffd "')
            pb(b'"\xfe"', '"\ufffd"')
            pb(b'"\xff"', '"\ufffd"')
            pb(b'"\xff\xfe"', '"\ufffd\ufffd"')
            pb(b'"\xfe\xfe\xff\xff"', '"\ufffd\ufffd\ufffd\ufffd"')
            pb(b'"\xef\xbf"', '"\ufffd"')
            pb(b'"\xe0\xa0"', '"\ufffd"')
            pb(b'"\xf0\x9f\x98"', '"\ufffd"')
            pb(b'"\xef\x93\x94\x95"', '"\uf4d4\ufffd"')
            # Lone continuation bytes with no leading starts
            pb(b'"\xbf"', '"\ufffd"')
            pb(b'"\x80"', '"\ufffd"')

            # Multiple lone continuation bytes
            pb(b'"\x80\xbf"', '"\ufffd\ufffd"')
            pb(b'"\x80\xbf\x80"', '"\ufffd\ufffd\ufffd"')

            # Lone starter byte of 2-byte sequence
            pb(b'"\xc0 "', '"\ufffd "')

            # Single never-valid bytes
            pb(b'"\xfe"', '"\ufffd"')
            pb(b'"\xff"', '"\ufffd"')

            # Multiple never-valid bytes
            pb(b'"\xff\xfe"', '"\ufffd\ufffd"')
            pb(b'"\xfe\xfe\xff\xff"', '"\ufffd\ufffd\ufffd\ufffd"')

            # Truncated 2-byte sequence (only 1 byte)
            pb(b'"\xc2"', '"\ufffd"')

            # Truncated 3-byte sequences (only 2 bytes)
            pb(b'"\xef\xbf"', '"\ufffd"')
            pb(b'"\xe0\xa0"', '"\ufffd"')

            # Truncated 4-byte sequence (only 2 or 3 bytes)
            pb(b'"\xf0\x9f"', '"\ufffd"')
            pb(b'"\xf0\x9f\x98"', '"\ufffd"')

            # Bad continuation byte (restored as ASCII)
            pb(b'"\xe1\x28\xa1"', '"\ufffd(\ufffd"')  # )

            # The following all fail when using SIMD and need to be fixed in the SIMD parser
            if which != 1:
                continue

            # Overlong 2-byte sequence for U+0000 (should be `0x00`)
            pb(b'"\xc0\x80"', '"\ufffd\ufffd"')

            # Overlong 3-byte sequence for U+0000 (violates boundary)
            pb(b'"\xe0\x80\x80"', '"\ufffd\ufffd\ufffd"')

            # Overlong 4-byte sequence for U+0000 (violates boundary)
            pb(b'"\xf0\x80\x80\x80"', '"\ufffd\ufffd\ufffd\ufffd"')

            # High surrogate code point
            pb(b'"\xed\xa0\x80"', '"\ufffd\ufffd\ufffd"')

            # Low surrogate code point
            pb(b'"\xed\xb0\x80"', '"\ufffd\ufffd\ufffd"')

            # Too large first codepoint
            pb(b'"\xff\x80\x80\x80"', '"\ufffd\ufffd\ufffd\ufffd"')


    def test_find_either_of_two_bytes(self):
        sizes = []
        if has_sse4_2:
            sizes.append(2)
        if has_avx2:
            sizes.append(3)
        sizes.append(0)

        def test(buf, a, b, align_offset=0):
            a_, b_ = ord(a), ord(b)
            expected = test_find_either_of_two_bytes(buf, a_, b_, 1, 0)
            for sz in sizes:
                actual = test_find_either_of_two_bytes(buf, a_, b_, sz, align_offset)
                self.ae(expected, actual, f'Failed for: {buf!r} {a=} {b=} at {sz=} and {align_offset=}')

        q = 'abc'
        for off in range(32):
            test(q, '<', '>', off)
            test(q, ' ', 'b', off)
            test(q, '<', 'a', off)
            test(q, '<', 'b', off)
            test(q, 'c', '>', off)

        def tests(buf, a, b):
            for sz in (0, 16, 32, 64, 79):
                buf = (' ' * sz) + buf
                for align_offset in range(32):
                    test(buf, a, b, align_offset)
        tests("", '<', '>')
        tests("a", '\0', '\0')
        tests("a", '<', '>')
        tests("dsdfsfa", '1', 'a')
        tests("xa", 'a', 'a')
        tests("bbb", 'a', '1')
        tests("bba", 'a', '<')
        tests("baa", '>', 'a')

    def test_esc_codes(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb('12\033Da', '12', ('screen_index',), 'a')
        self.ae(str(s.line(0)), '12')
        self.ae(str(s.line(1)), '  a')
        pb('\033xa', ('Unknown char after ESC: 0x%x' % ord('x'),), 'a')
        pb('\033c123', ('screen_reset', ), '123')
        self.ae(str(s.line(0)), '123')
        pb('\033.\033a', ('Unhandled charset related escape code: 0x2e 0x1b',), 'a')

    def test_csi_codes(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb('abcde', 'abcde')
        s.cursor_move(5)
        pb('x\033[2@y', 'x', ('screen_insert_characters', 2), 'y')
        self.ae(str(s.line(0)), 'xy bc')
        pb('x\033[2;7@y', 'x', ('CSI code @ has 2 > 1 parameters',), 'y')
        pb('x\033[2;-7@y', 'x', ('CSI code @ has 2 > 1 parameters',), 'y')
        pb('x\033[-0001234567890@y', 'x', ('CSI code @ is not allowed to have negative parameter (-1234567890)',), 'y')
        pb('x\033[2-3@y', 'x', ('Invalid character in CSI: 3 (0x33), ignoring the sequence',), '@y')
        pb('x\033[@y', 'x', ('screen_insert_characters', 1), 'y')
        pb('x\033[345@y', 'x', ('screen_insert_characters', 345), 'y')
        pb('x\033[345;@y', 'x', ('screen_insert_characters', 345), 'y')
        pb('\033[H', ('screen_cursor_position', 1, 1))
        self.ae(s.cursor.x, 0), self.ae(s.cursor.y, 0)
        pb('\033[4H', ('screen_cursor_position', 4, 1))
        pb('\033[4;0H', ('screen_cursor_position', 4, 0))
        pb('\033[3;2H', ('screen_cursor_position', 3, 2))
        pb('\033[3;2;H', ('screen_cursor_position', 3, 2))
        pb('\033[00000000003;0000000000000002H', ('screen_cursor_position', 3, 2))
        self.ae(s.cursor.x, 1), self.ae(s.cursor.y, 2)
        pb('\033[0001234567890H', ('screen_cursor_position', 1234567890, 1))
        pb('\033[J', ('screen_erase_in_display', 0, 0))
        pb('\033[?J', ('screen_erase_in_display', 0, 1))
        pb('\033[?2J', ('screen_erase_in_display', 2, 1))
        pb('\033[h')
        pb('\033[20;4h', ('screen_set_mode', 20, 0), ('screen_set_mode', 4, 0))
        pb('\033[?1000;1004h', ('screen_set_mode', 1000, 1), ('screen_set_mode', 1004, 1))
        pb('\033[20;4;20l', ('screen_reset_mode', 20, 0), ('screen_reset_mode', 4, 0), ('screen_reset_mode', 20, 0))
        pb('\033[=c', ('report_device_attributes', 0, 61))
        s.reset()

        def sgr(*params):
            return (('select_graphic_rendition', f'{x}') for x in params)

        pb('\033[1;2;3;4;7;9;34;44m', *sgr('1;2;3;4;7;9;34;44'))
        for attr in 'bold italic reverse strikethrough dim'.split():
            self.assertTrue(getattr(s.cursor, attr), attr)
        self.ae(s.cursor.decoration, 1)
        self.ae(s.cursor.fg, 4 << 8 | 1)
        self.ae(s.cursor.bg, 4 << 8 | 1)
        pb('\033[38;5;1;48;5;7m', ('select_graphic_rendition', '38:5:1'), ('select_graphic_rendition', '48:5:7'))
        self.ae(s.cursor.fg, 1 << 8 | 1)
        self.ae(s.cursor.bg, 7 << 8 | 1)
        pb('\033[38;2;1;2;3;48;2;7;8;9m', ('select_graphic_rendition', '38:2:1:2:3'), ('select_graphic_rendition', '48:2:7:8:9'))
        self.ae(s.cursor.fg, 1 << 24 | 2 << 16 | 3 << 8 | 2)
        self.ae(s.cursor.bg, 7 << 24 | 8 << 16 | 9 << 8 | 2)
        pb('\033[0;2m', *sgr('0;2'))
        pb('\033[;2m', *sgr('0;2'))
        pb('\033[m', *sgr('0'))
        pb('\033[1;;2m', *sgr('1;0;2'))
        pb('\033[38;5;1m', ('select_graphic_rendition', '38:5:1'))
        pb('\033[58;2;1;2;3m', ('select_graphic_rendition', '58:2:1:2:3'))
        pb('\033[38;2;1;2;3m', ('select_graphic_rendition', '38:2:1:2:3'))
        pb('\033[1001:2:1:2:3m', ('select_graphic_rendition', '1001:2:1:2:3'))
        pb('\033[38:2:1:2:3;48:5:9;58;5;7m', (
            'select_graphic_rendition', '38:2:1:2:3'), ('select_graphic_rendition', '48:5:9'), ('select_graphic_rendition', '58:5:7'))
        s.reset()
        pb('\033[1;2;3;4:5;7;9;34;44m', *sgr('1;2;3', '4:5', '7;9;34;44'))
        for attr in 'bold italic reverse strikethrough dim'.split():
            self.assertTrue(getattr(s.cursor, attr), attr)
        self.ae(s.cursor.decoration, 5)
        c = s.callbacks
        pb('\033[5n', ('report_device_status', 5, 0))
        self.ae(c.wtcbuf, b'\033[0n')
        c.clear()
        pb('\033[6n', ('report_device_status', 6, 0))
        self.ae(c.wtcbuf, b'\033[1;1R')
        pb('12345', '12345')
        c.clear()
        pb('\033[6n', ('report_device_status', 6, 0))
        self.ae(c.wtcbuf, b'\033[2;1R')
        c.clear()
        s.cursor_key_mode = True
        pb('\033[?1$p', ('report_mode_status', 1, 1))
        self.ae(c.wtcbuf, b'\033[?1;1$y')
        pb('\033[?1l', ('screen_reset_mode', 1, 1))
        self.assertFalse(s.cursor_key_mode)
        c.clear()
        pb('\033[?1$p', ('report_mode_status', 1, 1))
        self.ae(c.wtcbuf, b'\033[?1;2$y')
        pb('\033[2;4r', ('screen_set_margins', 2, 4))
        c.clear()
        pb('\033[14t', ('screen_report_size', 14))
        self.ae(c.wtcbuf, b'\033[4;100;50t')
        self.ae(s.margin_top, 1), self.ae(s.margin_bottom, 3)
        pb('\033[r', ('screen_set_margins', 0, 0))
        self.ae(s.margin_top, 0), self.ae(s.margin_bottom, 4)
        pb('\033[1 q', ('screen_set_cursor', 1, ord(' ')))
        self.assertTrue(s.cursor.blink)
        self.ae(s.cursor.shape, CURSOR_BLOCK)

        s.reset()
        pb('\033[3 @', ('Shift left escape code not implemented',))
        pb('\033[3 A', ('Shift right escape code not implemented',))
        pb('\033[3;4 S', ('Select presentation directions escape code not implemented',))
        pb('\033[1T', ('screen_reverse_scroll', 1))
        pb('\033[T', ('screen_reverse_scroll', 1))
        pb('\033[+T', ('screen_reverse_scroll_and_fill_from_scrollback', 1))

        c.clear()
        pb('\033[?2026$p', ('report_mode_status', 2026, 1))
        self.ae(c.wtcbuf, b'\x1b[?2026;2$y')
        c.clear()
        pb('\033[?2026h', ('screen_set_mode', 2026, 1))
        pb('\033[?2026$p', ('report_mode_status', 2026, 1))
        self.ae(c.wtcbuf, b'\x1b[?2026;1$y')
        pb('\033[?2026l', ('screen_reset_mode', 2026, 1))
        c.clear()
        pb('\033[?2026$p', ('report_mode_status', 2026, 1))
        self.ae(c.wtcbuf, b'\x1b[?2026;2$y')

    def test_csi_code_rep(self):
        s = self.create_screen(8)
        pb = partial(self.parse_bytes_dump, s)
        pb('\033[1b', ('screen_repeat_character', 1))
        self.ae(str(s.line(0)), '')
        pb('x\033[7b', 'x', ('screen_repeat_character', 7))
        self.ae(str(s.line(0)), 'xxxxxxxx')
        pb('\033[1;3H', ('screen_cursor_position', 1, 3))
        pb('\033[byz\033[b', ('screen_repeat_character', 1), 'yz', ('screen_repeat_character', 1))
        # repeat 'x' at 3, then 'yz' at 4-5, then repeat 'z' at 6
        self.ae(str(s.line(0)), 'xxxyzzxx')
        s.reset()
        pb(' \033[3b', ' ', ('screen_repeat_character', 3))
        self.ae(str(s.line(0)), '    ')
        s.reset()
        pb('\t\033[b', ('screen_tab',), ('screen_repeat_character', 1))
        self.ae(str(s.line(0)), '\t')
        s.reset()
        b']]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]'

    def test_osc_codes(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        c = s.callbacks
        pb('a\033]2;x\\ryz\033\\bcde', 'a', ('set_title', 'x\\ryz'), 'bcde')
        self.ae(str(s.line(0)), 'abcde')
        self.ae(c.titlebuf, ['x\\ryz'])
        c.clear()
        pb('\033]\x07', ('set_title', ''), ('set_icon', ''))
        self.ae(c.titlebuf, ['']), self.ae(c.iconbuf, '')
        pb('1\033]ab\x072', '1', ('set_title', 'ab'), ('set_icon', 'ab'), '2')
        self.ae(c.titlebuf, ['', 'ab']), self.ae(c.iconbuf, 'ab')
        c.clear()
        pb('\033]2;;;;\x07', ('set_title', ';;;'))
        self.ae(c.titlebuf, [';;;'])
        c.clear()
        pb('\033]2;\x07', ('set_title', ''))
        self.ae(c.titlebuf, [''])
        pb('\033]110\x07', ('set_dynamic_color', 110, ''))
        self.ae(c.colorbuf, '')
        c.clear()
        pb('\033]9;\x07', ('desktop_notify', 9, ''))
        pb('\033]9;test it with a nice long string\x07', ('desktop_notify', 9, 'test it with a nice long string'))
        pb('\033]99;moo=foo;test it\x07', ('desktop_notify', 99, 'moo=foo;test it'))
        self.ae(c.notifications, [(9, ''), (9, 'test it with a nice long string'), (99, 'moo=foo;test it')])
        c.clear()
        pb('\033]8;;\x07', ('set_active_hyperlink', None, None))
        pb('\033]8moo\x07', ('Ignoring malformed OSC 8 code',))
        pb('\033]8;moo\x07', ('Ignoring malformed OSC 8 code',))
        pb('\033]8;id=xyz;\x07', ('set_active_hyperlink', 'xyz', None))
        pb('\033]8;moo:x=z:id=xyz:id=abc;http://yay;.com\x07', ('set_active_hyperlink', 'xyz', 'http://yay;.com'))
        c.clear()
        payload = '1' * 1024
        pb(f'\033]52;p;{payload}\x07', ('clipboard_control', 52, f'p;{payload}'))
        c.clear()
        pb('\033]52;p;xyz\x07', ('clipboard_control', 52, 'p;xyz'))
        c.clear()
        pb('\033]22;?__current__\x07', ('set_dynamic_color', 22, '?__current__'))

    def test_dcs_codes(self):
        s = self.create_screen()
        c = s.callbacks
        pb = partial(self.parse_bytes_dump, s)
        q = hexlify(b'kind').decode('ascii')
        pb(f'a\033P+q{q}\033\\bcde', 'a', ('screen_request_capabilities', 43, q), 'bcde')
        self.ae(str(s.line(0)), 'abcde')
        self.ae(c.wtcbuf, '1+r{}={}'.format(q, '1b5b313b3242').encode('ascii'))
        c.clear()
        pb('\033P$q q\033\\', ('screen_request_capabilities', ord('$'), ' q'))
        self.ae(c.wtcbuf, b'\033P1$r1 q\033\\')
        c.clear()
        pb('\033P$qm\033\\', ('screen_request_capabilities', ord('$'), 'm'))
        self.ae(c.wtcbuf, b'\033P1$rm\033\\')
        for sgr in '0;34;102;1;2;3;4 0;38:5:200;58:2:10:11:12'.split():
            expected = set(sgr.split(';'))
            c.clear()
            parse_bytes(s, f'\033[{sgr}m\033P$qm\033\\'.encode('ascii'))
            r = c.wtcbuf.decode('ascii').partition('r')[2].partition('m')[0]
            self.ae(expected, set(r.split(';')))
        c.clear()
        pb('\033P$qr\033\\', ('screen_request_capabilities', ord('$'), 'r'))
        self.ae(c.wtcbuf, f'\033P1$r{s.margin_top + 1};{s.margin_bottom + 1}r\033\\'.encode('ascii'))
        pb('\033P@kitty-cmd{abc\033\\', ('handle_remote_cmd', '{abc'))
        p = base64_encode('abcd').decode()
        pb(f'\033P@kitty-print|{p}\033\\', ('handle_remote_print', p))
        self.ae(['abcd'], s.callbacks.printbuf)

        c.clear()
        pb('\033[?2026$p', ('report_mode_status', 2026, 1))
        self.ae(c.wtcbuf, b'\x1b[?2026;2$y')
        pb('\033P=1s\033\\', ('screen_start_pending_mode',))
        c.clear()
        pb('\033[?2026$p', ('report_mode_status', 2026, 1))
        self.ae(c.wtcbuf, b'\x1b[?2026;1$y')
        pb('\033P=2s\033\\', ('screen_stop_pending_mode',))
        c.clear()
        pb('\033[?2026$p', ('report_mode_status', 2026, 1))
        self.ae(c.wtcbuf, b'\x1b[?2026;2$y')


    def test_oth_codes(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb('a\033_+\\+\033\\bcde', ('draw', 'a'), ('Unrecognized APC code: 0x2b',), ('draw', 'bcde'))
        pb('a\033^+\\+\033\\bcde', ('draw', 'a'), ('Unrecognized PM code: 0x2b',), ('draw', 'bcde'))
        pb('a\033X+\\+\033\\bcde', ('draw', 'a'), ('Unrecognized SOS code: 0x2b',), ('draw', 'bcde'))

    def test_graphics_command(self):
        from base64 import standard_b64encode

        def enc(x):
            return standard_b64encode(x.encode('utf-8') if isinstance(x, str) else x).decode('ascii')

        def c(**k):
            for p, v in tuple(k.items()):
                if isinstance(v, str) and p != 'payload':
                    k[p] = v.encode('ascii')
            for f in 'action delete_action transmission_type compressed'.split():
                k.setdefault(f, b'\0')
            for f in ('format more id data_sz data_offset width height x_offset y_offset data_height data_width cursor_movement'
                      ' num_cells num_lines cell_x_offset cell_y_offset z_index placement_id image_number quiet unicode_placement'
                      ' parent_id parent_placement_id offset_from_parent_x offset_from_parent_y'
            ).split():
                k.setdefault(f, 0)
            p = k.pop('payload', '')
            k[''] = p
            return ('graphics_command', k)

        def t(cmd, **kw):
            pb('\033_G{};{}\033\\'.format(cmd, enc(kw.get('payload', ''))), c(**kw))

        def e(cmd, err):
            pb(f'\033_G{cmd}\033\\', (err,))

        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        uint32_max = 2**32 - 1
        t('i=%d' % uint32_max, id=uint32_max)
        t('i=3,p=4', id=3, placement_id=4)
        e('i=%d' % (uint32_max + 1), 'Malformed GraphicsCommand control block, number is too large')
        pb('\033_Gi=12\033\\', c(id=12))
        t('a=t,t=d,s=100,z=-9', payload='X', action='t', transmission_type='d', data_width=100, z_index=-9)
        t('a=t,t=d,s=100,z=9', payload='payload', action='t', transmission_type='d', data_width=100, z_index=9)
        t('a=t,t=d,s=100,z=9,q=2', action='t', transmission_type='d', data_width=100, z_index=9, quiet=2)
        e(',s=1', 'Malformed GraphicsCommand control block, invalid key character: 0x2c')
        e('W=1', 'Malformed GraphicsCommand control block, invalid key character: 0x57')
        e('1=1', 'Malformed GraphicsCommand control block, invalid key character: 0x31')
        e('a=t,,w=2', 'Malformed GraphicsCommand control block, invalid key character: 0x2c')
        e('s', 'Malformed GraphicsCommand control block, no = after key')
        e('s=', 'Malformed GraphicsCommand control block, expecting an integer value')
        e('s==', 'Malformed GraphicsCommand control block, expecting an integer value for key: s')
        e('s=1=', 'Malformed GraphicsCommand control block, expecting a , or semi-colon after a value, found: 0x3d')

    def test_deccara(self):
        s = self.create_screen()
        pb = partial(self.parse_bytes_dump, s)
        pb('\033[$r', ('deccara', '0;0;0;0;0'))
        pb('\033[;;;;4:3;38:5:10;48:2:1:2:3;1$r',
           ('deccara', '0;0;0;0;4:3'), ('deccara', '0;0;0;0;38:5:10'), ('deccara', '0;0;0;0;48:2:1:2:3'), ('deccara', '0;0;0;0;1'))
        for y in range(s.lines):
            line = s.line(y)
            for x in range(s.columns):
                c = line.cursor_from(x)
                self.ae(c.bold, True)
                self.ae(c.italic, False)
                self.ae(c.decoration, 3)
                self.ae(c.fg, (10 << 8) | 1)
                self.ae(c.bg, (1 << 24 | 2 << 16 | 3 << 8 | 2))
        self.ae(s.line(0).cursor_from(0).bold, True)
        pb('\033[1;2;2;3;22;39$r', ('deccara', '1;2;2;3;22;39'))
        self.ae(s.line(0).cursor_from(0).bold, True)
        line = s.line(0)
        for x in range(1, s.columns):
            c = line.cursor_from(x)
            self.ae(c.bold, False)
            self.ae(c.fg, 0)
        line = s.line(1)
        for x in range(0, 3):
            c = line.cursor_from(x)
            self.ae(c.bold, False)
        self.ae(line.cursor_from(3).bold, True)
        pb('\033[2*x\033[3;2;4;3;34$r\033[*x', ('screen_decsace', 2), ('deccara', '3;2;4;3;34'), ('screen_decsace', 0))
        for y in range(2, 4):
            line = s.line(y)
            for x in range(s.columns):
                self.ae(line.cursor_from(x).fg, (10 << 8 | 1) if x < 1 or x > 2 else (4 << 8) | 1)
